(Part (a))
Line 7: Line 7:
 
<math> (1) X_{k}[n-a] = d[n-k-a] </math><br><br>
 
<math> (1) X_{k}[n-a] = d[n-k-a] </math><br><br>
 
<math> (2) Y_{k}[n-a] = (k+1)^2 d[n-(k+1)-a] </math><br><br>
 
<math> (2) Y_{k}[n-a] = (k+1)^2 d[n-(k+1)-a] </math><br><br>
As shown in (2), <math> (k+1)^2 </math> does not get shifted. Thus,
+
As shown in (2), <math> (k+1)^2 </math> does not get shifted. Thus, a shift made in <math> X_{k}[n] </math> does not accordingly shift <math> Y_{k}[n] </math> <br><br>
 +
 
 +
== Part (b) ==

Revision as of 15:20, 11 September 2008

Part (a)

No. This system is not time-invariant. The general equation of the system is as follows.

$ X_{k}[n] = d[n-k] $

$ Y_{k}[n] = (k+1)^2 d[n-(k+1)] $

Shifting $ X_{k}[n] $ by a constant "a" yields $ X_{k}[n-a] $

Shifting $ Y_{k}[n] $ by a constant "a" yields $ Y_{k}[n-a] $

$ (1) X_{k}[n-a] = d[n-k-a] $

$ (2) Y_{k}[n-a] = (k+1)^2 d[n-(k+1)-a] $

As shown in (2), $ (k+1)^2 $ does not get shifted. Thus, a shift made in $ X_{k}[n] $ does not accordingly shift $ Y_{k}[n] $

Part (b)

Alumni Liaison

Abstract algebra continues the conceptual developments of linear algebra, on an even grander scale.

Dr. Paul Garrett